High-z Compaction to “Blue”Nuggets and Quenching to Red...

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Avishai Dekel The Hebrew University of Jerusalem

November 2014

High-z Compaction to “Blue” Nuggetsand Quenching to Red Nuggets

Barro+ 2013-14; Dekel & Burkert 2014; Zolotov+ 2014

“Blue” Nugget

Red Nugget

Red Nuggets

z~2 M~1011M�

Re~1 kpc low-SFR

Van Dokkum, Franx, Kriek, Bouwens, Labbe+ 08,10,14, Damjanov+09, Newman+10, Damjanov+11, Whitaker+12, Bruce+12, …

Dekel & Burkert 2013

Wet Compaction

Inflow is “wet” if inflow > SFR

Compact stellar spheroid → dissipative “wet” inflow to a “blue nugget”

In violent disk instability (VDI): torques drive AM out and mass in

Expect compact nuggets:- at high z, where fgas is high- for low spin λ, where initial Rgas is low

1SFR

inflow 2cold

1sfr >≈≡ − fw ε 2.002.0 coldsfr ≥≤ fε

Wetness parameter

Cosmological Simulations

Run by CeverinoCode: AMR ART (Kravtsov, Klypin) 3x30 galaxies zoom-inMax resolution 25 pc Max resolution 25 pc SN and radiative feedback

Collaborators:Mandelker, Danovich, Tweed, Zolotov, DeGraf, Inoue Krumholz+, Burkert+, Bournaud+, Primack+, Faber+, Genzel+

Fraction of bulge stars born in

Zolotov, Dekel, Mandelker, Tweed, DeGraf, Ceverino, Primack 2014

Wet Origin of Bulge in Simulations

in bulge

bulge stars born in different components

Most of the bulge stars formed in the bulge → wet inflow

Observations: Blue Nuggets –> Red Nuggets Barro+ 13 CANDELS z=1-3

Evolution: diffuse compaction quenchingEvolution: diffuse → compaction → quenching

central density

RN

BN

Compaction and quenching

Zolotov+ 14 ART cosmological simulations, res. 25pc, rad fdbk, no AGN

Compaction and quenching

self-gravitating Mstars>Mdm

gas

starsDM

mergers

mergers +VDI

wet inflow > SFR

SFR~outflow~recycling

outflow

inflow

SFR

wet compaction max density core: blue nugget

gas + young stars

vela v2 07

vdi disk core depletion: a hole and a ring

wet compaction max density core: blue nugget

stars

vela v2 07

green nugget red nugget + envelope

Blue Nugget – Red Nugget

blue nugget red nugget

gas stars gas stars

gas depletion from core, gas ring may form, -> inside-out quenching

stellar core remains dense from BN to RN

dense gas core -> dense stellar core

naked red nugget

Blue Nugget – Red Nugget

red nugget + envelope = elliptical

a stellar envelope may gradually grow by dry mergers

Inside-Out Quenching:Slower Quenching in the Outer Disk

inner 1 kpc whole galaxy

Inside-Out Quenching

Tacchella+ 2014 profiles of sSFR (=SFR/Mstar) at z~2 galaxies

sSFR

Stellar Component at z=2.3, edge-on

Overall Sersic n=2-4Classical bulge n=3-5

Ceverino+ 2014

“line width” evolution in simulated galaxies

Inoue, Zolotov+

extended disk

blue nugget red nugget

compaction

quenching

BN

RN

Barro+ 14

stars: rotation and dispersiongas: mostly rotation

RN

What is the Trigger of wet Compaction?

- VDI-driven inflow (Dekel, Burkert 14)

- Mergers (major, minor) (Barnes, Hernquist 91; Hopkins+ 06)

- Tidal compression (Dekel+03; Renaud+14)

- Counter-rotating streams (Danovich+14)

- Return of recycled low-AM gas (Elmegreen+ 14)

Gas streams + mergers along the cosmic web

AMR RAMSESTeyssier, ADbox 300 kpcres 50 pcz = 5 to 2.5

Hi-z galaxies are fed by intense streams,including minor and major mergers

Tweed, Dekel, TeyssierRAMSES Res. 50 pc

disk

streams

Ceverino, Dekel, Bournaud 2010 ART 35-70pc resolution

How do the streams join the disk?

interface region

A messy interface region:breakup due to shocks, hydro and thermal instabilities, collisions between streams and clumps, heating

30 kpc

gas density

An Extended Tilted Ring about the Disk

expressway entrance

stream lines30 kpc

Clumpy Disk: streams & mergersz=4-2.110 kpc

Ceverino, Dekel et al.

Violent disk instability (VDI) and mergers (mostly minor) work in concert

VDI deviates from linear Toomre instability VDI deviates from linear Toomre instability Q=2-5 -> nonlinear instability stimulated by in-streams with minor mergers

Violent Disk Instability (VDI) at High zCeverino+ ART-AMR cosmological simulations at 25pc resolution

highly perturbed, clumpy rotating disk: H/R ~ σ/V ~ fcold ~ 0.2

Observations vs. Simulations

Elmegreen et al

What is the Trigger of wet Compaction?

- VDI-driven inflow (Dekel, Burkert 14)

- Mergers (major, minor) (Barnes, Hernquist 91; Hopkins+ 06)

- Tidal compression (Dekel+03; Renaud+14)

- Counter-rotating streams (Danovich+14)

- Return of recycled low-AM gas (Elmegreen+ 14)

VDI-Driven Inflow: Gas + Clump Migration

Ceverino, Dekel, Bournaud 10

Wet Inflow when Gas Disk has Low Spin

low-spin disk -> high Σmax

Simulations (Zolotov+14) confirm model predictions (Dekel, Burkert 14)

compression – compaction – star formation - outflow

gas depletion - quenching

Compaction by Tidal CompressionDekel, Devor, Hetzroni 2003

Halo core

stripping

Counter-rotating Streams

Rv

alignment with disk

counter-rotating

impact parameter

counter-rotatinginflow: J-~0.7J J=J+-J-

in torbit: J-~0.15Jdisk

Counter-rotation -> CompactionDyda, Lovelace+14 (proto-stellar disks)

+ -

+ oscilations

+ - - -

The Quenching Mechanism

Wet compaction: inflow > SFR+outflow

High SFR and no gas supply to the center: inflow < SFR+outflow � quenching attempt

- disk has shrunk � no immediate gas supply to center- disk has shrunk � no immediate gas supply to center- massive bulge suppresses VDI-driven inflow (morphological quen.)- AGN outflow

Long-term quenching? Hot Halo

Diffuse SFG -> “Blue” Nuggets -> Red Nuggets

Downsizing:

More massive galaxies- compactify earlier- to higher density Σ1 , Σe

- quench more efficiently

more massive

less massive

Hesitatnt vs. Decisive Quenching

sSF

R

-1.5

-0.5

low mass, low z high mass, high z

sSF

R

-0.5

+1.5

Mass and Central Density at Quenching

72%

successful quenching in a narrow range of halo masses & above a threshold ~1011.5M

quenching attempts in a range of halo masses

Mstar

Mhalo

Virial Shock HeatingDekel & Birnboim 2006

Kravtsov+

slow cooling -> shock

in hi-z massive hot halos

critical halo mass ~~1011.8Mʘ

11 −− < compresscool tt

fast cooling –> no shock

in hi-z massive hot halos cold streams penetrate

Mvir [Mʘ]

all hot

1014

1012

cold filaments

in hot medium

MshockMshock>>M*

Mshock~M*

Cold Streams in Big Galaxies at High z

M*

1010

0 1 2 3 4 5

redshift z

all cold

Mshock

Dekel & Birnboim 06

Two Quenching Mechanisms: Bulge & Halo

Compact gaseous bulge -> gas removal by high SFR, outflow, AGN, Q-quenching

quenched

outflow, AGN, Q-quenching

In halos > 1012 M�

-> long-term shutdown of gas supply by virial shock heating

Woo, Dekel, Faber, Koo+ 14

Compact bulge and halo quenching

star forming

But each can quench by itself

The Quenching Mechanism

Wet compaction: inflow > SFR+outflow

High SFR and no gas supply to the center: inflow < SFR+outflow � quenching attempt

- disk has shrunk � no immediate gas supply- massive bulge suppresses VDI-driven inflow- massive bulge suppresses VDI-driven inflow- AGN outflow

If halo is massive (hot) � starvation of gas supply � long-term quenching

If halo is less massive � gas supply to a new disk� new compaction and SFR … until the halo is massive (hot)

Modes of Evolution

sSFR Halo quenching

high z, fastlow z, slowquenched

Halo quenchingmaintenance

diffuse compactΣ

sSFR

hi M & Σgas disk → wet inflow → hi gas compactness → starburst

Compact quenching gas consumptionstellar & AGN fdbkmorph. bulge quenching

lower M & Σgas disk →

moderate compactness

star forming

maintenance

Role of AGN Feedback in Quenching?

Kocevski+ 14

star forming main sequence SFGs

Gradients Across the Main Sequence

)1(SFingas η+−≈ MMM &&&

ffgasSF / tMM ε≈&

bathtub model:

±0.3 dex

Mstar

sSFR

quenched

inSF MM && ≈

2/51-in )1(Gyr03.0M

zM

sSFR +≈><≈><&

→ steady state:

→ time evolution of main-sequence zero point:

Compaction and quenching

Zolotov+ 14 ART cosmological simulations, res. 25pc, rad fdbk, no AGN

main sequence

Mstar Mhalo

star forming

blue nuggetshort tdep

high fgas

Diffuse SFG

Gradients Across the Main Sequence

Mstar

sSFR/(1+z)2.5

quenched

red nugget

green nuggetlong tdep

low fgas

Gradients Across the Main Sequence

Genzel+ 2014 z=0-2.5

tdep~sSFR-0.5 fgs~sSFR+0.5

tdep=Mgas/SFR fgs=Mgas/Mstars

star forming

main sequence

blue nuggetshort tdep

high fgasDiffuse SFG

Small Scatter about the Main Sequence

Mstar

sSFR/(1+z)2.5

quenched

main sequence

red nugget

green nuggetlong tdep

low fgas

At late times

massive halo

Conclusions

High-z massive galaxies are fed by cosmic-web streams with mergers:they are gas-rich disks undergoing violent disk instability (VDI)

A characteristic sequence of events in most galaxies:

- Wet compaction by streams with mergers and VDI to compact SFGs (“blue” nuggets): rotating flattened spheroids with high dispersion,above the main-sequence, short depletion time, high gas fraction above the main-sequence, short depletion time, high gas fraction

- High SFR+AGN, outflows, massive self-gravitating bulge �fast quenching inside-out to compact spheroids (red nuggets) then star-forming gas rings and stellar envelopes (ellipticals)

- Long-term quenching by hot massive halo

- Quenching downsizing:massive galaxies quench earlier, efficiently, at higher central densitiesless massive galaxies : hesitant quenching till halo shutdown

The High-z “Hubble” Sequence

Red nuggets

Compact ellipticals

Clumpy disks

No bars Perturbed spiral patterns

Blue nuggets

Starburst in a compact bulge